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NASA SP-5976 (05)January 1970
UTI,.I TIONM
(NASA-SP-5£76{05)) M_CHANICAL DEVICES: A N76-21555COMPILATICN Technology Utilization (_ASA)
]9 p HC $1.00 CSCL 131Unclas
GI,/37 2q616
MECHANICAL DEVICES
_S._
•-:_ II
NATIONAL AERO._g|IIf|L'S AND SPACE i_,
1976014467
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Foreword
The National Aeronautics and Space Administration has established aTechnology Utilization Program for the dissemination of information ontechnological developments which have potential utility outside the aerospacecommunity. By encouraging multiple application of the results of its research anddevelopment, NASA earns for the public an increased return on the investment inaerospace research and development programs.
Compilations are now published in nine broad subject groups:SP-5971: Electronics- Components SP-5976: Mechanics
and Circuitry SP-5977: MachinerySP-5972: Electronics Systems SP-5978: FabricationSP-5973: Physical Sciences TechnologySP-5974: Materials SP-5979: Mathematics andSP.5975: Life Sciences Information Sciences
When the subject matter of a particular Compilation is more narrowly defined, itstitle describes the subject matter more specifically. Successive Compilations in eachbroad category above are identified by an issue number in parentheses: e.g., the (03)in SP-5972 (03).
This Compilation describes a collection of new technology items that should be ofinterest to mechanical engineers, machinists, and others who design or work withmechanical devices. Section 1 contains articles on several new or modified tools,
Section 2 describes a number of sp_.cialized mechanical systems, and the last sectionis devoted to valves, bearings, and other parts that might be used with larger systems.
Additional technical information on items in this Compilation :an be requestedby circling the appropriate number on the Reader Service Card included in thisCompilation.
The latest patent information available at the final preparation of thisCompilation is presented on page 36. For those innovations on which NASA hasdecided not to apply for a patent, a Patent Statement is not included. Potential usersof items described herein should consult the cognizant orgal_ization for updatedpatent information.
We appreciate comment by readers and welcome hearing about the relevanceand utility of t_-. information in this Compilation.
NOTICE@Thisdocumentwaspreparedunderthesponsorshipof the NationalAeronauticsandSpaceAdministration.Neitherthe UnitedStatesGovernmentnoranypersonactingon behalfof theUnitedStatesGovernmentassumesanyliabilityresultingfromtheuseof the informationcontainedin this
_ document,or warrantsthatsuchuse willbe freefromprivatelyownedrights.
, For sale by the NationalTechnical Information Service, Springfield,Virginia 22161
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1976014467-002
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Contents
SECTION I. TOOLS AND DEVICESVariable Load Indicator ........................................... 1
Antislipping System Improves Wire Saw Pertbrmance .................. 2: Beam Lead Forming Tool .......................................... 3
Checkout and Alinement Tool ...................................... 4
Field Close-Tolerance Hole Enlargement ............................. 6 ...Universal Drill Jig ................................................ 8Stud-Guided Reamers ............................................. 9
Self-Adjusting Assembly Jig ........................................ 10 !
SECT1ON 2. SYSTEMS
Redundant Screwjack ............................................. I lEmergency-Escape Device ......................................... 12Reverse Paper-Tape Adapter for Adding Machines and Calculators ....... 13Easy Manual Operation of Overhead Garage Doors: A Concept .......... 14Mechanical Nonlinear Function Generator ............................ 15
Positive-Locking Lever-Adjustment Mechanism ....................... 16Flange Design for Large-Scale Modular Assembly Jigs .................. 18Detachablc Spring-Loaded Indexing Accessory for
: Modular Tooling Systems ........................................ 20 :
Standardized Braces for Modular Tooling System ...................... 22 ,_
SECTION 3. COMPONENTS
Electrofusible Quick-Release Device ................................. 23,_ Trirotational Wide.Angle Thrust Joint ............................... 24• Universal Inverted Flexure ......................................... 25
Grease-Lubricated Spiral-Groove Gyro Bearings ....................... 26Bearing Retention Device .......................................... 27 "'Bearing Preload Spacer ............................................ 28 _
New Bearing Is Repairable While in Service: A Concept ................. 30 _Thermally Actuated Valve ......................................... 31Shock Absorbing Connector/Clamp ................................. 32 _
: Hermetically-Sealed Motion Transmitter ............................. 34
• Shock Mitigator .................................................. 35
PATENT INFORMATION .............................................. 36
1976014467-003
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, Section I. Tools and Devices
VARIABLE LOAD INDICATOR
Plns
Movabl_
Vernie, Main Scale Sleeve Guided
Scale (Integral Hex) Nut
Variable Load Indicator
A newweighingdevicewasdevelopedformeasuring During measurement,the load producesa gaploadsasa functionof its elongation.The deviceis betweenthe sleeveanda guidednut whichrotatescompact, simple, and inexpensive.It does not require with the sleeve but allows the gap to open or close.presetting and will measureany load from zeroto its Sincethe sleeveandnut threadsareof differentpitch,yield point. Because of its low cost relative to other they travel at slightly different speeds. The sleeveload indicatorssuch as straingauges, the device can moves faster and will overtakethe nut, thus closingbe usedasa turnbuckle for tensioning straps, rods, or the gap. Gap closure brings rotation to a halt. Thecables whereaccuratepreloadingis critical, direction and amount of sabsequent load changeare
The stretching, due to load, is measured by the obtained by comparing new readings relative toamountof rotation in a threaded sleeve (see figure), previousreadings.Since a single thread gives little rotation and largedisplacementfor typicallysmall loads, a differential Source:W. T. Appleberryofthread mechanism is employed to give large sleeve McDonnellDouglas Corp.rotationfor little displacement(on the orderof six or undercontracttomore times). This provides more accuracyin reading MarshallSpaceFlightCenterthe scales. A scribed line on the sleeve indicates (MFS-21728)preload whenalined with a line on the integral hex.The design allows a 500-pound (227-kg) load to be CircleI on ReaderService Card.obtained at 60° rotationwith +10 percent maximumerror.
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] 9760 ] 4467-004
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"_ MECHANICAL DEVICES
ANTISLIPPING SYSTEM IMPROVES WIRE SAW PERFORMANCE
IdlerPulleys
)riveBelt
Motor
Support
DrivePulley
Idler Spool
AdjustableIdler Pulley
Wire
DriveSpool
Idler Spool
This system prevents slippage in a wire saw by The improvement in performance offered by thisproviding sufficient friction to turn the idler spools, system, combined with its low cost and applicability toeven when the turns of wire on the spools do not existing equipment, should render it of interest toprovide sufficient friction, industries employing wire saws.
The system, which is readily incorporated onexisting machines, entai!s the addition of a variable- Source: E. A. Gallo ofposition idler pulley to the drive-belt train. The Service TechnologyCorp.position of this pulley controls the tension on the drive under contract tobelt, which in turn, determines the frictional force Johnson Space Centerbetween the drive-belt idler pulleys and their (MSC-13508)supporting drums. The rotational force, imparted bythe pulleys to the drums, is transmitted to the wire Ctrcle2onReaderServtceCard.idler spools. Thus, the position of the additional idler
: pulley controls the rotational force of the idler spoolsand permits simple adjustments to prevent wireslippage.
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1976014467-005
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TOOLS AND TECHNIQUES 3
BEAM LEAD FORMING TOOL
Upper Carriage TableAdjustment
.,_lnsert
Outboard _ Inboard"" Lead Lock
: Carriage @ 0 I
r Adjusiment 0 i ILocknut !
' Table' Adjustment
Adjustment ICarriageAct I C
Locking
Jew
Lock•\" and Release
Manufacturers of fiat-pack electronic devices, such The adjusting screws and the insert are preset to theas integrated circuit packages, have a variety of tools required position dictated by the bend of the leads.for bending the beam leads. Most of these tools, how. and the outboard locking jaw of the carriage is lockedever. are designed for bending the leads to a fixed on the other end of the lead. The carriage is thenangle, moved upward by a carriage actuator, until it has
A new tool, designed for table-top manua, reached the upper adjustment screw which stops theoperation, can bend leads to any desired angle up to carriage at the preset bend angle. As the final step of90°. It can be readily adapted to electrical, hydraulic, the operation, the yoke lock is released and is adjustedor pneumatic systems, vertically to clear the bent lead. The outboard locking
The tool can handle |_,dd lengths to 1/4 in. (0.6 jaw is released, and the flat pack removed from thecm). The desired angle of the lead is formed by posi- device.tioning the flat pack on the tool table (see figure), aridthe table is adjusted vertically to aline the lower side of Source: P. W. Clemons of
the lead with the inboard lead lock of the yoke. The Sperry Rand Corp.lead is then inserted and locked between the jaws of under contract tothe yoke. The carriage is then adjusted to a specified Marshall Space Flight Centerlength required for the bend. (MFS.22133)
Circle 3 on Reader Sen, ice Card.II
1976014467-006
4 MECHANICAL DEVICES
CHECKOUT AND ALINEMENT TOOL
// ,oooo,.\\I I ll_I_,,rg.t I i
Hoist
Rocket-MotorSupport
Upper Interface Mountingend Alinement Tool
LowerInterface
Mounting
Calibrated
L-Pin
__.,,, 1)AO_ _ Tem0o,,_ i_o't_w_zu., su..o. ':
, OF1,cos_O-_zAdapter
Interface Plate
Figure 1. Support Structure With Alinement Tool
1976014467-007
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TOOLSANDTECHNIQUES S
Push-PullScale
Spotter
Micrometer
CalibratedArm
TargetAdapter
0
Figure2. Thrust-Vector$1muietlonandLocation
In multiengine rocket vehicles which do not have vector with respect to a target plate is determined by
active stabilization systems, rocket-motor support the use of a spotter punch and a micrometeralinement is critical, A combination tool checks the (Figure 2}.
rocket-motor s.pport.structure interface geometry
(Figure I) and ascertains the simulated location of the Source: S. Hornyak andthrust vector of each motor (Figure 2). W. Vobejda of
The tool is positioned and attached securely to each Martin Marietta Corp.
individual rocket.motor support in turn (Figure 1), under contract to
allowing mounting bolt alinement and span to be Langley Reseat :h Centerverified. While so positioned, the location of the (LAR-l1257)motor thrust vector is simulated by means of a
_. calibrated arm. The exact location of the simulated Clrcle4onRmderSewtceC,_Ill
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1976014467-008
_) MECHANICAL DEVICES
FIELD CLOSE-TOLERANCE HOLE ENLARGEMENT
A new field technique makes it possible to enlarge A drill fixture is attached loosely to a structure withholes with great precision without machine shop a hole to be enlarged. The alinement pin is inserted tofacilities. Or"the three steps in the operation (i.e., its stop depth, the loose drill fixture is tightened, andpositive ]oc_.tion, reaming, and burnishing to size), the alinement pin is removed. A reamer and a nosethe last is the specific improvement in bringing the bushing then are affixed to the drill fixture, with thehole to final size. Figure I illustrates the components nose bushing being used for precise location andand their use. alit,ement. The reamer is 0.0025 cm (0.001 in.)
smaller than the required minimum hole diameter.After reaming, the drill assembly is removed.
Alinement Pin Structure
Drill Nolm-Bu|hlngBushingDr_ll
Hole to beed
BurnlshlngToOl
Figure 1. Close Tolerance Hole Enlsrgement
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1976014467-009
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• TOOLS AND TECHNIQUES 7
• 2.
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?p ,¢
t_r__ ' ,. ..: .:,,:- _/
, /g \,. %,•; ,
: %,'
- .,,,,_i_ '. b/
• _ ' , |
( I<,., _,
-_._ m,lr_- • •
Figure 2, A_r-Driven Drill Used to Enlsrl_e Hole
Next a roller burnishing tool is hand-fed into the Source: C. S. Schedler of
hole and is adjusted so that there is a slight resistance The Boeing Co.to rotation. At that setting, the hole is burnished by under contract to
rotating the tool, removing it, and noting the hole size Kennedy Space Centerfrom the setting. The size noted is used to bring the (K5C-10341)hole to the exact specification. After readjustment tothe specified size the burnishing tool is hand-rotated Circle .5on ReoderSer_ice Card.again in the hole at which time the diameter is formedto the required close tolerance. Figure 2 shows anair-driven automatic-advance drill being used topower the reaming operation.
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1976014467-010
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8 MECHANICAL DEVICES
. Un_HI_ Drill Jig
l)rillinlg of holesst different •niglesto the flat plane insertedthroulghthe drill block and guided st theoften requiresexpensivetools such as s radial am selectedangle.dflll press. Now, an inexpensive jib has been designed To hold the entire assembly steady, several types ofthat can stendHy guide the drill st selected enf0es to clamp bracket mounts are svstlabk for supportin8the flat plane from any direction, the bevel bodies (see figure). In edditJon, another type
The jig shown in the figure u_es two mutually ofdrill block may be used, to guide the different sizesperpendicular bevel bodies desiignedto set the drill bit of drill bits, by simply selecting • proper hole on thest 15° intervals from QO° to 45° to the flat plane. Each drtll.seloctor drum.bevel body has igrooves to correspond to 15° intervslmtinp. A drill block used for guiding the dr_ll bit has Source: E. J. Stringer of• spline on one side to enpse the _ove on the bevel Rockwell lnteruatJoual Corp.body st • selected angle. Angles are set by loosening under contract tnwinS nuts on eith_r or bach bodies, tilting the drill Marshall Space Flight Center
. block to the desired snlgie until the spline engagesthe (MF5.24464)iproovc,knd tighteningthe nuts. The drill bit is then
Ck_ 6 on Reader_5,k-eI III
1976014467-011
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: TOOLS AND TECHNIQUES 9
J_ STUD-GUIDED REAMERS
MotorDrive
(PressFit orTaper Lock)
• |
SpiralCieerlmce
Roomer GroovesWith internal
Guide Hole Plate Fixture
Stud GuideRuiner
The internal reamer 8uide shown in thc figure The tool can be used for pre_ise reaminfl of holes
permits holes to be reamed in r_lricled-lCCC'.s 1.27 cm (0.5 in.) and larger in diameler. The mainlocations, since the 8uide requires less tooling advantaacofthcdesignstcmsfromtbealinedsupporlclearance than correspondinll drill bu_hinas or pilots, of the reamer by the stud 8uidcs.
Thb liuide has sc_.ral otl_r advantal_oous features.Spiral 8rooves on the internal stud 8uide allow Source:R. A. Marzulloofexcellentcoolantflow ar,dchip removal.The wearing RockwellInternationalCorp.action of reamer teeth on the Buide b eliminated, so under contract to
tool life is superior to that obtained with drill Jobnson Space Center
bushinjs. In addition, specialundersizedrillbushinp (MSC.Iq_4)arenotrequired,andonestudguidecanbeusedforseveral reamers. No _rtber documenlatio_ is avai_al_.
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1976014467-012
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|0 MECHANICAL DEVICES
SELF-ADJUSTING ASSEMBLY JIG
Self-AdjuSttn 0 Jig
Ordinary jigsandfixtures for holdingparts in place end. together with the adjustableshims, provides anwhile furnace brazing often do not accommodate adjustableclamping force for holding together partsthermal expansion and co_*raction, resulting it; to be joined. The hinged end pivots to compensatemisalincd, deformed, or incomplete joints. Conven- automatically for thermal expa,sion ;rod contractiontional holding devices must often be tailored to each while maintaining a constant force on parts.job, and their bulk frequently constitutes an Parts and joints are readily visible and accessible.undesirable heat sink that lengthens the time required in furnace brazing, this accessibility allows thefor the brazing operation, optimum placement of thermocouplrs tl',at is impor-
The lightweight jig shown in the ,igure self-adjusts tant in experimental work where time and tempera-for thermal expansion an,; contraction, to hold parts tore parameters must be established. The jig. which isbeing joined under constant pressure and i._ correct simple, easy to use, durable, and maintenance-treealinement, during the entire joining operation. The jig can be used with several joining methods to bondconsists of a fiat bed with o,le fixed end and one parts of many sizes and shapes.adjustable hinged end. The hinged end is adjustableboth at the hinge and at the weighted beam. The Source: Michael J. Haaserweighted beam and the beam arm are slotted to Lewis Research Centerpermit sliding adjustments. The hinge Fin may be (LEW.I2034)removed and relocated along the fiat bed to
compensate for the size_, of pans. Thus, the hinged No.lfirtl_er documentatiem is av¢ihsble.
1976014467-013
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11
Section 2. Systems
REDUNDANT SCREWJACK
Ball Nut andScrew (Left-Hand) Differential
(or Any Nut/Screw) Gears
( 0 I@l,l,l,l@ll,l,l@,l,l,l,l,lll,DVIAl IN\ i@l,l@l,lll@,l,lll@ll[\ © ),,,,,,,
o,.,oJ,o,oo 'Rotary Input SWine(Rotates and
(Mechanical, Electrical, Reciprocates)Hydraulic)
$crewjacks used as actuators on aircraft flap nuts whichmovethe left-hand and right-hand screws,systems, and in other critical applications, may be extending or retracting them. The screws do notsubject to failures. These failures occur in the existing rotate but are firmly attached to the rcructure.double-nut and telescoping-type screwjacks when any if either nut/screw combination jams, the differen-of the nut/screw assemblies jam. These problems can tial gears will drive the other combination at twice itsbe overcome with a redundant screwjack that uses normal rate with no loss in overall performance.
differential gears to drive either one of the nut/screwassemblies, in the event that the other jams. Source: R. W. Benjamin of
The redundant screwjack (see figure) utilizes input Rockwell International Corp.gears to drive a rotary external splint which, in turn, under contract tomeshes with and drives an internal spline. The lohnson Space Centerinternal spline is designed to rotate and reciprocate (MSC-19200)with the external one. The internal ._pline also
supports the spider input to the differential gears. No tbrther documemation is available.These gears rotate the right-hand and left-hand ball
1976014467-014
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12 MECHANICAL DEVICES
EMERGENCY-ESCAPE DEVICE
Reel _ '_
Shock_" i Absorber
S , I
Frame
Cable
/' P,CableGuide
Emergency Exit Device
Burning buildings have been deathtraps ever since extends the shock absorber. The rotation of the reel isconstruction began. Even to this day, with all of our opposed by the absorber; the faster the reel rotates,fire safety regulations, fires, particularly in high-rise the greater the opposing action of the absorber. Thus,buildings, continue to trap inhabitants in their rooms, for the given weight of an individual in the harness, anbecause either the stairs are impassable, the elevators equilibrium is reached, resulting in a constant speed.do not operate, or no fire escapes are installed. With As designed, the device can lower a 150-1b (68-kg)all escapes blocked, the inhabitants either expire in person at a rate of 2 ft/s (0.6 m/s). Heavier personstheir rooms or jump to their death from windows. To will descend at a slightly faster rate, lighter oneseliminate the risk of jumping frem windows, several slightly slower. After the first person reaches ground,devices have been made to provide safe descent, the cable is retracted manually, by detaching one endUnfortunately, these devices are complicated to of the shock absorber from the frame and using it as aoperate and require some degree of athletic ability, rewinding handle. Alternately, a spring-loaded
A relatively-simple inexpensive escape device has ratchet, to retract the cable automatically after itbeen developed. Using a reeled steel cable, controlled reaches the ground, can be added to the device.by an automotive-type shock absorber, it allows safe The device is inexpensive to manufacture anddescent from a bur, ing building. The device is a assemble. It weighs 8 Ib (3.6 kg) and requires neithermetal frame containing a cable-wound reel and a skill, special knowledge, or athletic ability to operate.shock absorber (see figure). The cable is made of steel It is reliable and fireproof and can be deployedwires, capable of supporting a 1000-1b (454.kg)load instantly. In practice, it may be anchored to aand is long enough to reach the ground from most any permanent installation outside of a window or to awindow. One end of the shock absorber is attached wall inside.
firmlyto the frame; the other end is attached to a studon the reel center. Source: P. M. Broussard
in at_ er-.ergency, a man-carrying harness is Marshall SpaceRightCenterattached to the free end of the cable. As an individual (MFS-22720)descends from a window, the cable unwinds and
rotates the reel which, in turn, compresses and Circle TonReaderServiceCard.
1976014467-015
SYSTEMS 13
REVERSE PAPER-TAPE ADAPTER FOR ADDING
MACHINES AND CALCULATORS
Adding
Rewind
•":'":" Roll
f,
`____._::._i::_::._._:\_:_:_:_.::_`_:_._.._:_._`_::_.:_i::_i.".:'.".:'._,''".'._"._ __ Rewind-Roll
"___ "" DriveBelt
_ldentlcal Brackets
is UpsideDown)(TheOutsideBracket
CarrierRollerForMovingMachine
Adapterto UtilizeBothSidesof PaperTape
The adapter shown in the figure automatically rollers, to make the rollers rotate in opposite
rewinds paper tape to facilitate use of its reverse side directions. The paper tape is run through the machinein an adding machine or similar device. By using both and proceeds onto the adapter roller, where it is
sides of the paper tape, the cost per roll is essentially accumulated in a cou,;ter.clockwise manner., cut in half.
The adapter consists of two metal brackets, two Source: P. L Cayenne
spring-loaded rollers, two rubber bands, and two Kennedy SpaceCenterpaper guides. The reverse paper-tape adapter is fitted (KSC-10310)
onto an adding machine or a calculator. A rubber
band in the shape of a figure 8 is placed on the two No.lurther documentation is available.
1976014467-016
14 MECHANICAL DEVICES
EASY MANUAL OPERATION OF OVERHEAD GARAGE DOORS: A CONCEPT
A novel manually-actuated mechanism (see figure) of the apparatus permks the door to translate andcould easily raise or lower a two-section overhead rotate when opening or closing, and requires nogarage door; the Rolamite prilciple (see AEC-NASA vertical guides in the doorway. Once manuallyTech Brief 67-10611) is used to provide a controlled actuated by turning or pulling a handle, the Rolamitebut varying rate of ascent or descent, apparatus opens or closes the door without further
Rolamites traversing an overhead channel generate manual effort.forces that rotate a drum that maintains a controlled The rate of raising or lowering can be controlled bytension on a cable attached to the door. The geometry design characteristics based on the Rolamite princi-
ple. The mechanism is extremely quiet since rollingfriction is minimized and no vertical guides or rollersare required for vertical movement of the lowersection of the door.
The life of the mechanism should be long becausethe only stressed components are the cables and thecontoured bands of the Rolamites, all of which can
survive the average life of a residence. Installation issimplified by hanging the overhead channel from theceiling so that all necessary support is provided for the
\ door and mechanism. Apart from the latch, no coil\\ springs take part in movement of the door.
\ _',, Maintenance is minimal, because Rolamites require
\,_ \ \ no lubrication."_ Although the device is intended primarily for
i operation of home or industrial doors, it may be,_ applied where any type of vertical shielding or baffling[ needs to be raised or lowered. It may be inverted for
i raising a barrier from floor level without vertical_ ..t "_4. guides or supports.
...J
L [ / Source: C. J. Fuller of"_ i ..I- The Boeing Co.
p ", ,.
Kennedy Space Center(KSC-10555)
Garage-DoorSystem Circle 8 on Reader Service Card.
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1976014467-017
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SYSTEMS I ,S
MECHANICAL NONLINEAR FUNCTION GENERATOR
WireNo.1
Centers WireNo.2
ofRotation
J
Groove_ for Wires '_
SetScrewsInput:el ore= AtEndPointsOutput:e=ore= ofCamSurfaces
MechanicalNonlinearFunctionGenerator
Photographic cameras and many other instruments in the cam surfaces. One wire holds or moves theoften require a mechanism to convert a linear output cam in one rotational direction, and the othermechanical input, such as a shaft rotation, into a band or wire acts in the opposite direction. As themechanical output which is a nonlinear function of cams rotate, each wire roils off one cam and onto the
the input. An example is the logarithmic relation other. , •between the exposure control setting and the shutter Ideally the two cams are always in contact at one _ :opening. Noncircular gears and cam-and-follower point, but it, actuality a moderate gap is possiblesystems have been used to solve this problem, without hurting the accuracy or smoothness of
: However, noncircular gears have inherent backlash, opera(ion. The cams are prevented from slipping by :need lubrication, and are costly to manufacture. A the action of the two wires. Each wire joins the endcam-and-follower system requires either spring point of one cam to the corresponding end point of the
: loading to maintain contact or grooves that add other cam. The wires can be fastened to the cam endfriction and backlash. The cam-and-follower arrange- points in any suitable manner (the figure showsment is also less versatile if the output is to be a shaft setscrews, which are convenient for assembly androtation, adjustment purposes). Only moderate tension in the
' A nonlinear mechanical function generator avoids wires is required for smooth, zero backlash operation.these disadvantages. It has no backlash, minimum This device can be used wherever a nonlinearfriction, and the correct input/output relationship. It relationship is needed between a mechanical inputis similar in operation to a pair of noncircular gears, and an output. The device is not limited t.Although gear teeth are absent, the two gears (cams) logarithmic functions and can be designed to generateare in contact, or close to contact, at their pitch lines, almost any mathematical function that does notThe assembly of the two cams and wires is shown in reverse its slope or have discontinuities or excessivethe figure, ratios.
_ As one cam is rotated it rolls along the surface ofthe other. The ratio of the radii of the two cams at the Source: J. T. Sharpsteen ofpoint of contact deter,nines the rotational ratio for Perkin-Elmer Corp.that point. As the cams rotate, the ratio varies as the under contract totwo radii vary. The two cams are kept in posittve Johnson Space Centerangular relationship to one another by two small (MSC-14629)
; i! wires, which are secured at the end points of the camcontour surfaces and run in parallel shallow grooves Circle 9 on Reader Service Card.
1976014467-018
l0 MECHANICAL DEVICES
POSITrYE-LOCKING LEVER-ADJUSTMENT MECHANISM
A predetermined relationship between the inter- Valve-latching mechanisms often have failed fromfacing surfaces of a valve-latching mechanism can be interference between interfacing surfaces (X and Y inset up and maintained, even under limited accessi- Figure 1). This results from dimensional-tolerancebility, with a positive-tension lock. The lock may be variations reflected in the relative positions of theused with housings, adjuseable cams, levers, or surfaces. With the addition of adjustment provisionslinkages, in deep recesses where machines are to the lever, a definite clearance between surfaces Xrequired, and Y can be established and maintained, to ensure
consistent latching.
_ .... i "- , !., ._,.'_._: Clearance
[
x\/Surface Y _ Surface X
Latch Piston Ill
, SI_ Camt
I
Figure 1, Standard Valve-Latching Mlmhanlom
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1976014467-019
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SVSTEMS 17
_ Adjustment
Spacer_
Figure 2. Locking-Lever-Aclluetment Mechanism
The procedureis illustrated in Figure 2. Rotating When the adjustmentiscomplete,surfaceX is lockedthe t_ _ bolts in opposing directions imparts a in position by torquing the bolts. The spacer preventscorrespondingly-opposed rectilinear motion to the two inward bolt deflection under locking loads.conical washers. In turn, the motion of the conical
washers is transmitted through the conical mating Source: E. D. Storms ofsurfaces of the cam, with a resultant clockwise or Rockwell International Corp.
counterclockwise displacement of cam surface X. By under contract tothe proper opposing rotation of the bolts, lever surface Marshall Space Flight CenterX can be adjusted to a position that will provide the (MFS-24014)prescribed clearance with interlacing surface Y.
Circle 10 on Reader Service Card.
1976014467-020
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18 MECHANICAL DEVICES
FLANGE DESIGN FOR LARGE-SCALE MODULAR ASSEMBLY JIGS
A new technique has been developed fol attaching working platforms and reference points and planes forflanges to three-dimensional frameworks called large- the assembly-and-tool operation upon such largescale modular assembly jigs. These jigs are designed structures as spacecraft, aircraft, seagoing vessels.so that two or more of them may be assembled to and railcars.make a complete tooling-and-assembly jig. The The large-scale modular assembly jig (Figure 1) is aoverall assembly of such modules then provides rectangular parallelepiped in form and is made of
0
_ Modular
AssemblyJig
Box-BeamEnd Pad
Collar
Figure 2a. Collar on Box-Beam End
F_gure2b Locating Pad on Box-Beam End
1976014467-021
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SYSTEMS 19
three intersecting sets of unmachined box beamswelded together. From each surface of the weldedstructure, a number of beam ends project outwardly.Such members, owing to the weld method of DrillBit
Box-Beamconstruction, are approximately parallel, are spaced EnOfrom each other approximately to conform to a pre- SpecialDrilldetermined pattern, and terminate approximately in a _ Bushingcommon plane.
Using the new technique, locating pads are Locatinginstalled on the beam ends so as to provide tooling Pad'_planes (tops, bottoms, and sides) oriented at 90° withrespect to each other (Figures 2a and 2b). Theseplanes are thus provided with tooling holes 3/4 in.(1.9 cm) in diameter, set on 77.00-in. (177.80-cm)
grid centers, which are accurately located with respect _ _Oowsls_to each other within 0.005 in. (_-0.013 cm). Combinedplanar deviation is held to 0.015 in. (¢0.038 ca). yBecausethe tooling is held to closetolerancewhilebeing fabricated, special alinement during the Figure2¢. In|tlllgtlonlindAlinementofbuildup of severalmodulesis not necessary. Locating PadandCollar
The techniqueconsistsof alining and dowelingsetsof precision-machined pads and collars to the lack of coplanarity, and lack of parallelism.The newunmachined square tubing ends of the modular technique provides a weldless method for securingassemblyjig, to provide distortion-free load-bearing flanges to the projecting ends of an unmachinedflanges. The floating pad-and-collar design permits box.beam framework in such a manner that thethe lateral alinementof pad centersrelativeto master flanged structure may be reused without modifi-grid-plate centers.The collar is connectedto the pad cation. One such framework may be readilyby a set of machine screws, passing through slightly assembled to another by simply matching the flangesoversize holes in the collar and into tapped holes in together and passing connecting members betweenthe pad. by a pair of dowel pins driven through preformed holes in the structures. So far as is known.registering holes in both members. The attachment this is the first large modular tooling that does not
• collars then permit movement for exact length and require special alinement of the flanged joints duringperpendicularity alinement, prior to being attached assembly.by dowels to the box.beam ends (Figure 2c). Thus theouter surfaces of the flanges are accurately coplanar Source: M. M. Gilman ofand are accurately spaced from one another according Rockwell lntern_,tional Corp. _
to the predetermu,: '_ pattern, under contract toIn the previous three-dimensional modules, the Johnson Space Center :
flanges are attached by welding. These all-welded (MSC-19372)structures have the usual disadvantages associated
with welding, e.g., lack of accurate dimensioning. Circle 11 on t_.eoderServlceCard.
J_
7_
1976014467-022
20 MECHANICALDEVICES
DETACHABLE SPRING-LOADED INDEXING ACCESSORY FORMODULAR TOOLING SYSTEMS
A new detachable spring-loaded indexing accessory The accessory latches into the tooling module byimproves the large.scale modular assembly jig rotating two latching fingers into grooves (Figure 2) inreported on in the preceding Compilation article the main structural posts of the modular assembly jig.(MSC- 19372). The accessory is used only when rigging The grooves in the module are provided by adjusting
and alining (indexing) a modular tooling component the spacing between the box-beam ends and theto a floor mo.nt or to another component, and it flanges before the flanges are pinned into place. Thisfacilitates the alinement of grid holes during the quick attach/detach feature permits the rapidas:_.mbly of the modules (Figure 1). When alinement removal of the indexing accessory for the installationis complete, the accessory is removed and replaced by of the assembly bolts after the module is alined.bolts and nuts.
Accessory
Jig Structure
o
MainStructural
POIt
Figure 1. Indexing A¢cesllory In Modular Tooling 8yltem
1976014467-023
SYSTEMS 2]
Unhooked Hooked !Position Position
T --'_a
1
_,, h ,! I '% o I
" LX_..J
StructuralPost
I
Ii 'I I
! o
Spring, as Shown, Is IPraloeded 318 In. i I
(Approximately 15 Ib) _ i Iand Provides
Approximately 40 Ib Pmesum
, , t - Sprln0-Retentlon
Lato.i.g II , _IF--T_I _ ,,'l; , / l_Jl , . i i i I(RofMenca)
4---hq : _ ti I _ -'- t Jf----* 4
! I I , !Figure 2. InltllllttOl'b lnd Oetlll of Indexing Accessory
The spring.loaded, bullet-no_d guide pin will not Source: M. M. Gilman of
jam or scratch the boltholes, since it retracts to avoid Rockwell International Corp.damaging the fixture yet snaps into place when undet contraet toassembly alinement is achieved. The accessory Johnson SpaceCentcrreduces fixture as._mbly time and maintenance co_ts, (MSC-19373) '
and it could readily be incorporated into many large itooling structures for damage.tree riy.ging and Cbclel2onRt, ad_$t,w_.'eCanLalinement. _
i i i ill
l
1976014467-024
i iI
J
22 MECHANICAL DEVICES
STANDARDIZED BRACES FOR MODULAR TOOLING SYSTEM
MailerGrid PIIII
I Slonldn..,m._ e ../ •Mounll._ (_,'_
Bu:hlnO ! /"" _ Endrl _. / _/'_111_{ Attachment!1 "_ t, j oo,,l )_I _ l
e/ :i _ s_.-N..\ X_I_ Enllrgld View o,/ II \\%_ 70170 Shoulder "_. "_ _ Slotted Mounl;n0 Boll/ II \\\\_s,,oo -s_;,;,- \ . X/ I: ... \\\\ A..,,, __a_ ,\ )iMIIIIr,o=,orM,_:"\\\\ _ _ N";/\
I !1 Plate \_ \_L 4rr • V V /A End
I ;I N\\\ " \I I! BreCl'_''_ _% _ SECTION A.A %. ,_F_ !1
Auembly
I !I .o.., \\ '_\ E.d \ /I Ream.l li _ __L__L___/" A,l.h_� "_ ;L/Ho_,
i----- so.oddin.-----I I s._,,_w,.ofI --- ;:_, j. j ,0,,0,r.. A..,,bly2= ,0000'_.-'---'1
Stlmdardlzecl Brece
A newstandardizedbrace hasbeendevelopedto be size bracesquaresa .r_O.in.by 70.in. (l.3-m by 1.8-m)used in conjunction with the large-scale modular triangle, and the secondsquaresa 70-in. by 70-in.assemblyjig described in a preceding Compilation (l.8-m by 1.8-m) triangle.article (MSC-19372). Specifically. the now brace The first step in the onsite assembly of the bracesimplifies the precision assembly of the Ioad.bea_ng consists of pinning the _eamed holes of the two end
• flanges incorporated into these modules by supporting plates to the appropriate holes on the master gridthe modular tooling master grids in a perpendicular plate using step pins, The end plates are then turnedposition, when assembled at the appropriate grid and alined under the center channel. The three piecespoints, with slip bushings and special bolts (see then are clamped, and the assembly is drilled andfigure). The design incorpot Ites slotted mounting reamed at the channel pilot holes. The pieces are thenbolts to center the end pins in the tooling plate surface removed and assembled with shoulder screws.planes, Because the brace can be made to precise
, lengths by using the master tooling grid plates, the Source: M. M. Gilman ofnew design permits the onsite assembly of precision Rockwell International Corp.braces with a minimum of large tooling, under contract to
The brace assemblies are made in kit form in two Johnson Space Centerdifferent sizes for fabrication onsite. The assembly (MSC.19374)consits of a central channel with two bolted and
dowelled end attachments as shown in the figure. One Circle 13 on Reoder Service Card.
1976014467-025
Seetlon 3. Components
ELECTROFUSIBLE QUICK-RELEASE DEVICE
Mounting Blmo
Fusible Link (Wire)
Electri_.ll
/ Contsctr Polt
) -J
, --....HOUSing
__ (Shown Approximately+ Four ;';ranElectricII Actual lille)
Llldl
[lectrofullblt Ouick-Relelll DlviCl
The device shown in the figure can be used to secure Although a wide range of electrically-conductivemechanisms in a locked condition until such time as tension links might be used, tests have shown thatthey must be released remotely for action. Although high-;trength l_rrous alloys work very well. Inexisting devices may be used for certain medium-sized automobiles and trucks the device could be used toand small mechanisms, this device is simpler, lighter, release fire extinguishers in engine compartments orand more reliable, cargoareasby pushingswitcheson dashboards.The
Small.diameter wire. 0.025 to 0.0,51cm (0.010 to application5of the devicecould be widespreaddue to0.020 in.), is used to apply a tension force to the its lowcostan_ basicsimplicity.mechanism being restrained. High-strength steel.alloy wire can be usedto providea _,ockingforce in Source:Morion L. Cloversofexcess of 222N (,50Ib). The holdingwire bear, on two Martin Marietta Corp.eccentric electrical contact poststhat age groovedto under contracttohelp s,_ure this fusible link, even when exposed to Langley ResearchCenterseverevibrational environments.When quick release (LAR- I I17_;is required,a smallelectricpulseof about 10to 20 Wfor 1or 2 secondsbrings the temperatureof the wire No.f_vtker documentation b o" tilable.between the two posts to a sufficiently elevated pointto produce failure of the wire, thus releasing themechanism being held.
1976014467-026
24 MIECH _NICAL DEVlCES
TRIROTATIONAL WIDE-ANGLE THRUST JOINT
A trirotational wide-angle thrustjoint shownin the The joint has several desirablefeatures.No specialfigure is basically a swiveled rod end pinned in a hardwareis required_ ,41itscomponents arcoff-the-trunnion-mounted cradle with antifriction roller shelf items. Any desired bearing preload can bebearings located at each point of relative motion. It establkbed, andthe design canbe modified readilytoprovidesthreedegreesof angularfreedom for use in a suit larger or smaller angles. Limit switches can besix-degrees-of-freedom (three angular and three providedto limit angular motion.translational)motion simulator. The joint has zero The housing, machined from high-strengthsteel, isbacklashunder shock load, is relatively light, and is as small as design requirements allow, to reducecharacterizedby low rrictionand a minimal number weight to an absolute minimum. Maintenance isof deflections.In addition, it has a capacity for large minimal since bearings are packed durinq assemblyangular motions exceeding those usually found in and have covers that protect them f. . contain-sphericalrod ends. ination.
F "I
dt° RolJ_
_qt _ S_I_. A.A
L_il(J m Link
Source:T. F. Ryanand H. L. AdairorKentrol Hawaii.Ltd.
Aetm'rm)leAH_H_b_y undercontracttoJohnsonSpace Center
(MSC.14451)
No l_nker documcnamioniJ av¢ilable.
1976014467-027
COMPONENTS 25
UNIVERSAL INVERTED FLEXURE
Asserr_bled Block Section Detail
A frictionless, inverted, universal pivot (two angular The device is symmetrical about the third (non-degrees of freedom about a common point) minimizes flexing) axis. Thermal expansion and contraction _:illthe effect of temperature changes and prevents over- not displace the flexural center from this axis. For thisstressingofthe flexing elements. The pivot is a flexure reason, temperature changes will not cause any
: block which can be readily fabricated from a single significant angular movement in a body suspendedpiece of material. It is first machined with external from the block, regardless of the material from whichsurfaces asshown in the diagram. Then the single side the block is made.
, hole and the vertical holes are bored through the The device is intended for inverted use: input andblock, and the four si.e holes are bored just deep output on the same side. However, it can easily beenough to intersect lhe centerline of the throfigh used in a normal, noninverted configuration byholes. The device maintains stiffness during boring attachment to the innermost block through theoperations so that accuracy is easily achieved without counter-bored potion of the single side hole.special restraining fixtures. Source: Wayne O. Hadland
l-v 'iy, six saw cuts are made to free the flexing Ames Research Centerelements; because of their width, they also provide the (ARC. 10345)limits of motion, that is, they are inherent limit stops.
Circle 14 on Reader Service Card.
I
1976014467-028
!I
F
t1!
'_-0 MECH? NICAL DEVICES
GREASE-LUBRICATED SPIRAL-GROOVE GYRO BEARINGS
_4.165 mm -_
_ _L _ /.!!!!//!il!J _ J_ / ,' I ", II I
BearingSpecifications:Number of Grooves= 7Land-to-Groove-Width Ratio = 1Groove Depth = 0.025 mm
Geometric Parameters of Conical Bearing
A theoretical study is available which examines, by addition optimization and manufacturing toleranceanalysis and testing, the suitability of lubricated data such as the influence of cone axis misalinementspiral-groove bearings for the spin axis of a gyro, such are included.as might be used for an auto pilot or a platform- Experiments conducted with air-turbine andstabilizing momentum wheel. Results indicate that motor-driven rotors, supported by conical bearingsbearings fitted with spiral grooves and lubricated with with a base diameter of 3 mm (0.12 in.) [angulargrease will develop _ full fluid film, provide high load momentum about 3x10 s g-cmZ/sec (l.02x103capacity, exhibit excellent tolerance to overload and Ib-in.Usec)], indicate the feasibility of using spiral-start.stop rubbing, and have a long operating life groove bearings in small gyros or large momentumunder certain conditions. The bearings must be wheels, provided the bearings meet the two require-designed so that the net lubricant flow out of the ments previously mentioned. Greases demonstratingclearance space is zero. The physical and chemical shear stability and having predictable and reproduci-properties of the lubricant must remain relatively ble properties have been developed and tested. Also,constant over the operating life. the properties of the base fluid, the thickener, and t[ e
A numerically implemented analysis, based on the grease formulation are given, along with the viscosityfinite element method, is presented for the general and vapor pressure measurements.class of spiral-groove bearings lubricated with anisoviscous Newtonian fluid. A test facility constructed Source: J. T. McCabe and T. Y. Chu offor validating the analysis, has shown it to be Franklin lnstitute Research Labsaccurate. Tests performed with an instrumented 10 under contract to
cm (3.9 in.) diameter journal provide data on film Marshall Space Flight Centerpressure and flow pattern history. A dead-ended (MFS-21662)
bearing with a spiral-grocve conical journal isanalyzed, and general parametric data generated. In Curie 13 on Reader Service Card.
1976014467-029
, l !
i tt
COMPONENTS 27
BEARING RETENTION DEVICE
_'_""- Housing
Bend OuterRaceTabs
BearingRetention
Ring
I
BearingRetentionDeviceon RollerBearingI
A novel method of retaining the outer races of roller material is a ductile alloy in order to prevent cracking
bearings allows smaller and lighter housings where a ot the tabs during clamping.
more rugged housing might normally be required. The method is only suitable for light loads and isThe method utilizes a thin metal bearing retention not intended to take any direct thrust loads. However,
ring with integral tabs and a narrow rim fitted into a for light loads, it is adaptable to other types of
groove machined in the housing wail. The outer bearings or cylindrical components that requirebearing race then is slipped into the housing bore, retention in a housing.
thus trapping the retaining ring in place. The tabs arethen bent over the outer race to retain the bearing (see Source: A. P. Swift of
figure). Rockwell International Corp.This method is relatively inexpensive in that no under contract to
drilling, tapping or threading operations, or threaded Marshall Space Flight Centerfasteners needing a locking device are required. The (MFS-19189)number of tabs can be varied to suit various
conditions such as loads and diameters. The ring Circle 16 on Reader Service Card.
I
1976014467-030
I
6
28 MECHANICAL DEVICES
BEARING PRELOAD SPACER
A preload spacer (fixed preload) has a well to A second type of preload spacer (spring preload)accept a spring washer. The controlled well depth has a depth-controlled well to provide the desiredprovides the desired preload when the spring washer is preload when the spring washer is compressed to thecompressed to the well-depth height. When the flat well depth, less the thickness of a preselected feelerwasher (see figure) makes contact with the conductive gauge. When the spring washer is compressed to thesurface on opposing sides of the spacer, the design desired amount, the spacing is determined by thepreload is established on the bearings. This condition feeler gauge and the desired preload is established.is identified by electrically sensing the initial contactbetween spacer and washer.
" "" _,, Sensing
P/;:Y///
Conductive __
SurfaceDivided ',1to
Quadrants
Outer _ _'_
D,ameterof Shorting _, _/
Washer
Circuit . Screw, Alternatively
SeDneSvii;egN_ _ /Threaded Shaft and Nut
,.) / ._, F,stWasher, Well _ /] Conductive
_ SwPr;_ger
Pre;oedSpacer _
Bearing Preload Spacer
1976014467-031
COMPONENTS 29
The preload spacer is dependent only on the axial spacer in less than 5 minutes within a tolerance of +10force applied to the bearing race to determine the percent. Preloads established on bearings by shim.amount of axial load. The electrical sensing device ruing or lapping cannot be checked on the completedwill sense less than 1° of angular movement. The assembly except by torque measurements. Preloadscorresponding axial movement for an 8-32 screw is can be checked easily on an assembly having a preloadless than0.000218 -m (0.000086 in.). A portion of this spacer, even when the unit is in operation. Definiteaxial movement is used to bring the axial load up to fixed preloads of fractions of a pound can bethe design load, so that the established load is very established on bearing assemblies using a preloadclose to the design goal. A more accurate control of spacer.the preload may be obtained by using a finer thread Previously, preioads of this type could be estab-on the hardware used to apply the load. Normal lished using matched bearing pairs with a tolerancemachining tolerances only are required for the on the applied preload of __.50percent. These preloadfabrication of an assembly using a preload spacer, spacers permit the establishment of bearing preloads,The well depth of the preioad spacer should be fully independent of tolerance on the rest of thecontrolled to _+0.0025 cm (0.001 in.). bearing assembly. Bearings can be preloaded to
Conventional bearing preloads are controlled by desired levels with accuracy limited only by the springvery tight dimensional tolerances or shimming. It washe- tolerance. Additionally the spring preload
: should be noted that 0.0003 cm (0.0001 in.) axial permits the assembly of unlike materials in a unitmovement of one race relative to the other in a bearing which operates under a varying thermal environmentpair will change the preload by 1.4 kg (3 ib). Torque and maintains approximately uniform loading over ameasurement is commonly used in bearing assembly wide thermal range.to measure the preload. However, false measurementmay result if a grease is used to lubricate the Source: E. Hollowayofassembly. The torque caused by the grease may be RCA Corp.
i sufficient to indicate a nonexistent preload, under contract to
Establishing a bearing preload using shims or Goddard Space Flight Centerlapping to obtain the final dimensions is a costly, time (GSC-10678)consuming process, and the final preload establishedmay not be the desired amount by at least a factor of No fi_rther documentation is available.two. Preloads can be established using a preioad
1976014467-032
30 MECHANICAL DEVICES
NEW BEARING IS REPAIRABLE WHILE IN SERVICE: A CONCEPT
A newly developed bearing has a structurJ race on I
which many individual bali or roller bearings run as _ |wheels. This design makes it possible to replace the __ ._L__ ....L Jindividual bearings while the unit is operating. -- r-c"_l _ 7-"_--J"
Figure 1 illustrates the assembly for a radial load, \ _ '/ |Thrust -= I X II I_'k_,J
and Figure2, for athrust load. The raceisattachedto Bearing -.'_'__.._ I V__.__'_ "-, R°llr_rn
°. ,1 I tOo,er..ceI'" 'aT"'
Wall Individually-Replaceable
Bearing Assembhes
Figure 2. Bearing Installation for Thrust Load
the outer wall ,if" the structure and the individual
bearing_ are mounted on an inner assembly. Theremoval of one of these individual bearings forreplacement or repair does not affect the others.
This bearing should be attractive for applicationsrequiring continuous or lengthy periods of operation.
.. although some positioning accuracy may be sacri-c--"t.____,.j"'-'7"_ Radii riced. The innovation may be o¢ interest toRoller "_] _3... _ .Beat ing
Bearing_ _ Race manufacturers of large, rotatable communications
_ antennas and rotating platforms for construction.. _I_ _ - ._-_=----- __ equipment.
i/I iI I _tnner Source: R. W. Benjamin ofwall Rockwell International Corp.
Individually-Replaceable under contract to
BearingAssemblies Johnson Space Center
• SECTION A-A (MSC- 17467)
Figure 1. Bearing Installation for Radial Load No_rther documentation is available.
i
1976014467-033
COMPONENTS 3l
THERMALLY ACTUATED VALVE
Inlet........ _ Port
_--'-_--X_ _ _ Resistance- Section A-A'
b,_ I..,=lp A/ Heater CoilsExit Port
A small, reliable, lightweight valve is designed to the upper edge of the cylinder under any conditions ofrelease a piessurized fluid in a single operation. An valve orientation or acceleration.effective seal in a one-shot valve is made by shrink- The fact that high stresses can be generated whenfitting a bali within a cylinder; thermal expansion of one member is shrink-fitted around a second memberthe cylinder, caused by a contiguous source of heat, is well known. With proper design and fabrication,will release the ball and open the valve, the seal produced between the seat and plug is
The valve (shown in the diagram) consists leakproof; in fact. the valve can be tested easily (whileessentially of a cylindrical body which is shrink-fitted sealed) any number of times with degradation becausearound the bail. When activated, a resistance heater of the absence of moving parts.fitted into the recess warms the cylinder and releases The valve can also be adapted for repeatedthe ball. The ends of the cylindrical body have a operation and can be made capable of being openedthreaded inlet and exit ports so that the valve can be without a pressurized fluid. For this configuration, aconnected to a fluid dispensing line. call or other suitably configured plug is released from
To set up the valve tbr the first time. the cylindrical the seat (after heating) by a compression springbody is oriented into a vertical position with the inlet interposed between the bali and the bottom of theport resting on a flat surface. The cylinder is heated in cylinder. A bellows brazed into a hole in the assemblythis position by placing it in a hot oven, by energizing closure disk, with a nominal capability of spring-likethe heater, or by some other means. When the action, holds the ball against the circular edge whilecylinder is cold, it is too small in diameter to permit fluid passes through the radial flutes cut into theentry of the ball; however, when the cylinder is hot, circular edge. When it is desired to close the valve, the
thermal expansion has increased its diameter, and the heater is again energized and a sufficiently great forceball drops into place. The ball normally would fall (provided by a mechanical linkage, pressurizedand be seated on the circular edge near the inlet port; hydraulic fluid, or some other means) is appliedhowever, the ball in the diagram is purposely set away through the center of the bellows to overcome thefrom the edge to emphasize the tact that hermetic force of the spring and the force (if any) applied to theclosure occurs at the contact zone between the ball plug by fluid flowing around it. When it has beenand the cylinder wall. Assembly of the valve is determined that the plug is properly located at thecompleted when the closure disk is screwed into place, seat, the heater is deactivated and, when the seat has
The sealed valve can be installed in a line and will cooled, the pa' _ageway through the valve will again behold back a pressurized fluid in the inlet cavity. To sealed.open the valve, the heater is energized; the cylindricalbody expands until it becomes large enough to release Source: Robert H. Silver ofthe ball. The pressurized fluid ejects the ball into the Cahech/JPLbody cavity, and flows around the sphere and through under contract tothe exit port. Radial flutes are cut into the circular NASA Pasadena Officeedge (show in detail in Section A-A/) so that once the (NPO-11846)valve has been opened the ball cannot effect a seal at
Circle 17 on Reader Service Card.i i
I
1976014467-034
i /I !
32 MECHANICAL DEVICES
SHOCK ABSORBING CONNECTOR/CLAMP
The connector/clamp incorporates a double over-center mechanism, utilizing two springs, one of which
can be made to operate the mechanism and the other _ .-_-_providing redundancy. The mechanism consists of a _, ,!
receptacle fitting and housing, floating strut, spher- i__ _iical hearings, piston, tension springs and overcenter y-,linkages. The connector/clamp may he used to
connect two structures; one being attached to thefloating strut, the other to the receptacle fitting. In
m
the open position, before release of the mechanism, ashock absorbing capability is provided by the tension
spring which supports the floating strut (Figure 1). In I
/ ov.c_,/ Position
2-In. Spherical -" Force
Allowance _ _ 9 Floating
_1Lateral • _.
Excursion-.---_ Socket
Receptacle Piston [
overcenterf A _ ILlnksge_ /] I Figure 2. Connectorl ClampHousing Structural Rigld-Clamp Mode
Framing
Member
this operating modeonlymechanicalspringloadsand•. system friction loads are transferred between struc-
' tures. Upon release of the mechanism, the tensionstrut _,- springs drive the overcenter linkage into the
overcenter position causing the conical surface on the
Spring floating strut to be pre-loaded into the receptaclefitting, thereby ensuring a rigid, load-bearingconnection (Figure 2). The cylindrical struts of theovercenter linkage are adjustable, providing aFigure 1. Connector/Clamp
Shock-AbsorberMode capability for overcenterand clamp-up forcecontrol.
I
1976014467-035
i I ri !
i i
COMPONENTS 33
Overcenter
/ Position
600 6
50O 5Retraction
Forc_Travel
40O 4 A13 m
g ®vn° Retraction _c• )rce "E
200 2
SpringForce
IO0 _ t
2 4 e 8 10
Spring Stroke(Inches)
Figure 3. Operating Loads
Three or more connector/clamps may be com- Source: D. G. Wetzlerof
' bined, by means of structural framing members, to McDonnell Douglas Corp.
form a stabilizing system. Axial alinements are under contract to
obtained by adjusting the studs in the floating strut. Marshall Space Flight Center
The graph of Figure 3 describes the operating Ioad,_ of (MF5.21680)the mechanism.
Circle 18 on Reader Service Card.
1976014467-036
,14 MECHANICAL DEVICES
HERMETICALLY-SEALED MOTION TRANSMITTER
Input Shaft
ConvolutedFlex
Member
Flex MemberSoldered or Brazed
to the Housing
An hermetically-sealed motion transmitter has been expected with the proper design ratio of the radius ofdeveloped which allows transmission of rotational or the crank arm, the length of the bar, and the diametersingle-planar arc motion through an hermetically of the convoluted member.
sealed chamber without the use of dynamic seal or This device may be of interest to pressure vesselcomplex mechanisms, designers and those who need to isolate equipment
Motion is transmitted between two shafts on the from a hostile environment.
same axis using a wobble bar that has its end pointscaptive in crank arms. A convoluted member of a Source: Robert L. Eckert of
highly-flexible fatigue-resistant metal (e.g., berrylium Rockwell International Corp.copper) is soldered or brazed to the shaft at the under contract towobble axis and to the housing, thus forming a seal Johnson Space Centerwithout the use of dynamic seals. (MSC-17348)
Each design application is limited to a maximumpressure differential. Excellent operating life can be No further documentation is available.
1976014467-037
COMPONENTS 35
SHOCK MITIGATOR
Low-cost aluminum foil can be used as a shock The crushed foil filled the clearance volume
mitigator where space limits the use of other energy, between the telescoping elements, thus taking out allabsorbing methods. The concept was developed in initial looseness and providing sufficient friction toorder to absorb the energy acquired in extending a prevent rebounding of the boom elements. Thetelescoping boom from a spinning rocket. In tests concept might be of use in the auto industry as asimulating the extension of the boom, there was low-cost shock-absorber for bumpers.reduction in peak shock from 300 g's without the foilto 9 g's witl" four wraps ef foil 0.0IS in. (0.0038 cm) Source: Robert H. Carrothick, initially 1-1/2 in. (3.81 cm)wide, on each of Goddard Space Flight Centertwo elements of the boom. The foil was crushed to (GSC-11097)
approximately 1/4 in. (0.63 cm).
No further documentatmn L5amilable.
1976014467-038
l T ,
3O
Patent Information
The following innovations, described in this Compilation, have been patented orare being considered for patent action as indicated below:
Variable Lead Indicator (Page I) MFS.21728and
Beam Lead Forming Tool (Page 3) MFS-22133and
Universal Drill Jill (Page 8) MFS.24464Inquiries concerning rights fp: the commercial use of these inventions should be
addressed to:Patent Counsel
Marshall Space Flight CenterCode CC01
Marshall Space Flight Center.Alabama 35812
Easy Mansul Operation of Overhead Gara|e Doors: A Concept (Page 14) KSC- 1055._Inquiries concerning rights for the commercial use of this invention should bc
addressed to:Patent Counsel
Kennedy Space CenterCode AD-PAT
Kennedy Space Center. Florida 32899
Unlvenml Inverted Flexure (Page 25) ARC-10345Inquiries concerning rights for the commercial use of this invention should be
addressed to:Patent Coun,_el
, Ames Research CenterCode 200.11AMoflett Field. California 94035
_.%+, COVelrlm+ml PltnttNl Oilier: IYPt.t]II-I+? It+lll+C }.11
1976014467-039